Electrical control system



June 19, 1945. R. H. SMITH ETAL ELECTRICAL CONTROL SYSTEM Filed Aug. 17, 1940 5 Sheets-Sheet 1 2:, INVENTQR.

Rosco-E H. J'mTH BY Ll. 0 YD Ari/am A zo/v A4. flaw/M M ATTORNEYS R. H. SMITH ETAL ELECTRICAL CONTROL SYSTEM June 19, 1945.

, 1940 5 Sheets-Sheet 2 Filedv Aug. 17

INVENTOR. Rosco: ff. SMITH L1. 0Y0 MILLER A [UN A4. DUNN/Ne MM am! k ud A7773 June 19, 1945. R. H. SMITH ETYALQ ELECTRICAL CONTROL SYSTEM Filed Aug. 17, 1940 5 Sffeets-Sheet 3 INVENTOR fiG.

{Roscoe H. Jm/Tu LLOYD E. MILLER 50m 44. Dam/ma Arm June 19, 1945'. R. H. SMITH ETAL 2,378,444

ELECTRICAL CONTROL SYSTEM Filed Aug. 17, 1940 5 Sheets-Sheet 4 v INVENTOR.

Rosco: H. JM/TH fig 4 BY 140w 5 M/LLER LEON M. DUNN/N6.

June 19, 1945. R. H. SMITH ET AL 2,373,444

ELECTRICAL CONTROL SYSTEM Filed Aug. 17, 1940 5 Sheets-Sheet 5 40 130 492 INVENTOR.

' v Rosco: H. J/wTH fiaj Moro M/LLER 1. [01V M. fiwww/va I Q/WM M ATTYS Patented June 19, H

Roscoe H; Smith and Lloyd E. Miller, Cleveland,

Ohio, and Leon M. Dunning, Boston, Mass., assignors to The Reliance Electric and Engineering Company Application August 17, 1940, Serial No. 353,102

25 Claims. (01. 101-178) Our invention relates in general to electrical control systems and more particularly to electrical control systems for cloth printing machines.

In the printing of cloth, the previous practice has been to print each roll of the cloth by passing it through the print machine as an individual run. This necessitated the threading of each roll separately and constituted a serious handicap in obtaining high speed production. Printing speeds have also been slow for the reason that linear speeds for printing the cloth have electrical control system for the entire machine stands out as one of the major improvements an constitutes the subject matter of this application. Our electrical control system not only gives great flexibility but also makes it possible to eliminate the time lost in starting or threadin each new roll of cloth in order to obtain the full benefit of the higher operating speed.

The cloth to be printed is unwound from a supplying reel onto an accumulating conveyor designated in the trade as a scray device. The accumulated cloth is then withdrawn from the scray device and after passing over a dancer roll and a group of tension rolls enters the print machine where'it travels in contact with a number of engraving rolls around the circumference of a large print machine cylinder. is printed is then directed to a plurality of drying cylinders which are called in the trade main cans or piece good cans"- from which the finished cloth is then pulled by a folding device which delivers the finished printed cloth into carts or boxes. The accumulating conveyor or scray device may be so designed as to permit the building up of enough cloth ahead of that taken away by the printing machine cylinder to com- .pletely unwind one roll and attach to its end the start of a fresh roll, thereby insuring continuous operation of the machine. At the folding device, as each seam comes along, the cart or box bein filled is pushed forward and the cloth is folded into another box or cart brought under the fold- The cloth after it ing device, leaving the seam between the boxes or carts to be out later.

Next to the cloth being printed, butbetween it and the main printing machine cylinder, is a web of cloth commonly known'as the back rey. This cloth is the full width of the engraving or printing rolls and takes up the ink on the ends of theengraving rolls beyond the selvage of the cloth being printed. The main purpose of the grey back is to keep the ink from being deposited on a blanket which is next to the grey back on the large printing cylinder. The grey back is unwound from a supply roll and pulled directly into the cloth printing machine from which it travels over a set of drying cylinders or cans, known as the grey back cans. The end of the grey back which is threaded through the machine is fixed or connected to the clothcoming from the unwinding supply roll, thus forming a continuous or endless back grey. At the end of the printing run, as the last roll of cloth to be printed'is being passed through the printing machine, the seam in the grey back is cut open and the grey back is wound up on a smaller winder called a batcher device.

The main drive for the cloth printing cylinder is applied to the several engraving rolls by a suitable gearing arrangement. The pressure of the engraving rolls on the large printing cylinder drives the latter by friction. In actual practice.

the circumferences of the engraving rolls vary between 16 inches to 24 inches for diiferent lengths of patterns being printed; Accordingly, the linear speed of the printing machine cylinder varies from a given speed of 'themain drive, dependin upon the circumferences of the engraving rolls. At the maximum linear speeds thedrive is designed to provide at least 300 yards per minute, which is made available even with the minimum size engraving rolls namely, the 16 inch circumference rolls, and at th minimum linear speeds the drive is designed to give as low as 10 yards per minute for threading or matching-up purposes, which is made available with the maximum size engraving rolls; namely, the 24 inch circumference rolls. Although this appears to be a 30 'to '1 speed range, it is actually 45 to 1 by reason of the variations in the diameters of the'engravins rolls. In threading the machine, the operator may run it at a low speed either by setting the mt" nditi n. In addition to the same main employed to energize the drive which drives the printing machine cylinder, individual sectional drives are applied to the other driven parts of the entire machine.

An object of our invention is to provide for operating the entire machine over a wide range of speeds, in such a manner as to have sufllcient power available to make the operation positive and reliable at any speed.

Another object of our invention is to provide for operating the machine under three distinct operating conditions; namely, that is to operate the machine under a jogging condition, under a run slow condition, or under a run fast condition.

Another object of our invention is to preselect the speed at which the entire machine will run under the run fast condition.

Another object of our invention is the provision of bringing the machine to a stop by first transferring from the run fast condition to the run slow condition and then transferring from the run slow condition to the stop condition.

Another object of our invention is the provision or bringing the machine to a rapid stop without passing through the run slow condition.

Another object of our invention is to provide for selectively energizing the main motor which drives the engraving rolls and the printing cylinder from a low voltage and a normal voltage generator to obtain the wide speed variations.

Another object of our invention is to provide for electrically energizing the main motor from i the low voltage generator under the jogging condition or under the slow run condition and to provide for energizing the main motor from the normal voltage generator under the higher speeds of the fast run condition.

Another object of our invention is to provide for preventing the main driving motor from being subjected to an electrical jar upon the transition from the low voltage generator to the normal voltage generator.

Another object of our invention is to provide for making the transition from the low voltage generator to the normal voltage generator, and vice versa, at a point or condition where the volta es of the two generators are relatively close together.

Another object of our invention is to provide for making the transition from the low voltage generator to the normal voltage generator, and vice versa, at a point or condition where the voltages of the two generators are relatively close together while the voltages oi! both generators are changing.

Another object of our invention is to provide a wide speed variation under the run fast condition by varying the field excitation of both the main driving motor and or the normal voltage generator.

Another object of our invention is the provision or a sectional electrical drive for the entire machine whereby the various elements may be operated individually or in unison.

Another object of our invention is to make the motor which drives the main printing cylinder to be governed by the speed of another motor of the sectional drive in order to compensate automatically for difierent diameters of the engraving rolls.

Another object or our invention is the provision of energizing the main motor from a generator source different from the generator source other sectionalized motors.

Another object of our invention is the provision of energizing the main motor from a generator source diilerent from the generator source employed to energize the other sectionalized motors, in order that the speed of the main motor may be varied both by the voltage impressed upon its armature and by its field excitation without disturbing the speed of the other sectionalized motors.

Another object oi! our invention is the provision of energizing the main motor from a generator source difierent from the generator source employed to energize the other sectionalized motors in order that a heavy or a light load on the printing cylinder does not disturb the voltage impressed upon the other sectionalized motors.

Another object of our invention is to make the motor which drives the main drying cans" to be the "master" or lead section of the sectional electric drive.

Another object of our invention is to govern the lineal speeds of the printing cylinder in accordance with the lineal speed or the main drying can by an electrical synchronous interlock having in combination therewith a differential regulator which influences the speed of the main motor driving the printing cylinder.

Another object of our invention is the provision of adjusting the tension of the printed cloth between the printing cylinder and the main drying can by shifting the relationship existing between the electrical synchronous interlock and the differential regulator.

Another object of our invention is to provide for varying the speed of some of the sectional motor drives by means of a buck-and-boost generator governed by a dancer roll rheostat.

Another object of our invention is to provide for varying the speed of some of the sectional motor drives by means of a buck-and-boost generator.

Another object of our invention is to provide for controlling the speed of some or the sectional drive through a buck-and-boost generator and a dancer roll rheostat in which the rheostat influences the field of both the buck-and-boost generator and the motor which is connected in circuit relation with the buck-and-boost generator.

Other objects and a fuller understanding of our invention maybe had by referring to the following description and claims, taken in conjunction with the accompanying drawings, in which:

Figure 1 represents a diagrammatic side elevational view or a complete cloth printing machine, showing the travel or the cloth being printed, the rey back, and the blanket, together with the electric motors for driving the various elements;

Fi ure 2 represents a single line electrical diagramot the controlsysteminwhichtheblocks represent diagrammatically a grouping of the various control elements which govern the operation 0! the electric equipment;

Figures 3, 4 and 5 are to be considered together as one complete electrical diagram for the entire electrical system.

With reference to Figure 1 o! the drawings. the cloth to be printed, being designatedby the reference character 2|, is supplied upon an unwindin reel in from which the cloth is withdrawn by'a pair or first pull rolls ll upon a scray device I! where the unwound cloth is permitted to accumulate. From the scray device the cloth is withdrawn by means 01' a second pair of pull rolls H from which the cloth travels over a dancer roll rheostat l4 into a system oi! tension rolls ll from which the cloth enters the printing cylinder II. The cloth, as it passes around the printing cylinder i6 is brought into contact with the engraving or printing roll I! which print the pattern or design upon the cloth.- The printed cloth upon leaving the printing cylinder l passes upwardly to a system of drying cylinders l5 which are Benerally referred to in the trade as main cans and which are located overhead in a balcony or on an upper floor. After the printed cloth is dried by the main cans it passes over a number of rollers to a pair of folding rolls I9 which convey the printed finished material intoa box or carton 20.

.The accumulating, conveyor or scray device I! may be designed so as to' permit the building up of enough cloth ahead of that being taken by the printing cylinder to completely unwind one roll so that a fresh or new roll may be put on the supply reel with the end of the cloth of the fresh reel stitched to the end of the cloth on the scray device, thereby insuring continuous operation of the machine.- The scray device comprises, briefly, an endless conveyorwhich rotates or runs around two spaced rollers so that as the cloth is accumulated thereon the weight of the cloth tends to drive the endless conveyor about the two spaced rolls. As an alternative, the conveyor may be driven slowly by some external means. At the folding rolls i9, as each seam comes along, the cart or box being filled is pushed forward and the cloth is folded into another box or cart brought under the folder, leaving the seams between the boxes to be cutapart later.

Next to the cloth being printed, but between it and the main printing machine cylinder, is the web of grey back which is indicated'by the refer ence character 24. This cloth is the full width of the engraving or printing rolls I! and takes up the ink on the ends of the engraving rolls beyond the salvage of the cloth being printed. The main purpose of the grey back is to keep this ink from being deposited on a blanket designated by the reference character 42 which is next to the grey back on the large printing cylinder 15. The blanket is next to the printing cylinder l5 and runs around the rollers 43. In threading the grey back, it is unwound from a supply reel.25 and passed over a plurality of spaced rolls 25, 21 and "and then around the printing cylinder l5 from which it passes over a series of spaced rolls 29, 50 and 3| to a dancer roll rheostat 32. The grey back then passes over a system of drying cylinders 34 which are generally known in the trade as back grey cans. The forward or threaded end of the gray back after passing over the grey back cans 34 is carried under a roll 55 up to a point in the neighborhood of the dotted line 55. Then the operator cuts the grey back material coming from the supply reel 25 at the dotted. line 15 and stltches'the twoadjacent ends of the grey back together to make an endless strip of material which runs continuously between the printing cylinder I5 and the grey back cans" as the printing machine is in operation; At the ends of the printing run, as the last roll of cloth to be- Dlmted'is being fed through the printing ma,-

- chine, the stitched seam in the grey back is cut cylinder IS, the grey back cans 34, the butcher device 45, the main cans l5, and the folding rolls .15 are represented respectively by the reference characters 5|, 52, 53, 54, 55, 55, 51 and 58. That is to say, each unit or element of the complete printing machine has its own individual driving motor, constituting a sectionalized electrical system of operation. The motor 54 is designated as the main motor drive and is arranged to be suitably geared to drive the several engraving rolls I! which in turn drive the printing cylinder l5 by frictional engagement. The circumferences of the engraving rolls [1, as illustrated by the dotted I circles, may vary between 16 inches and 24 inches for difierent lengths of patterns being printed. Accordingly, the lineal speed of the printing cylinder varies for a given speed of the main driving motor 54, depending upon the circumference of the engraving rolls. In actual operation the speed of the main driving motor is arranged to provide at least 300 yards per minute as the maximum speed and this is made available even with 16 inch circumference rollers. A speed in the neighborhood of 10 yards per minute is arrangedfor threading or matching-up purposes, and this is, obtainable even with the 24 inch circumference rolls. This actually sets up a 45 to 1 speed range,

due to driving through the variable diameter engraving rolls.

In our electrical control system; the main can motor 51 is the "master or lead section of the sectionalized electrical drive. In .order to keep -the.lineal speed of the printing cylinder 5 and the lineal speed of the main can l5 in unison or in synchrony, the speed of the main driving motor 54 is governed in accordance with the lead or master motor 51 that drives the main cans I8. The synchronizing of the lineal speed of the printing machine cylinder I5 with the lineal speed of the main cans I5, is accomplished by the employment of a synchronous transmitter 59 which is driven in response to the lineal speed of the printing cylinder l5 by a roll 50, a synchronous receiver 52 which is electricallyconnected to the synchronous transmitter 59 as indicated by the responsive to the lineal speed of the printing cylinder l5 through the synchronous transmitter 59, and the'other side of the differential regulator 53 is driven by the motor 51 through the drive indicated by the dash-dot line 58 and the variable pulleys 55. In the event that the lineal speed of the printing cylinder l5 tends to depart from open at a point in the neighborhood indicated by the dotted line 4| and the forward end'ot the srey back is then threaded into a batcher device 45 where it is wound on a take-up reel, after which the grey back may betaken away and cleaned or washed so that it may again be put upon the supplyreeLl! 1g another period otoperation.

The electric iiibtomfor first and secondpairofpullrolls II and ".thetension it, t e r011: I a the printing the lineal speed of the main cans it, the difl'erential regulator 53 is immediately operated to vary the speed of the main driving motor 54 to bring the linear speed of the printing cylinder II in? synchrony with that of the main cans II. The shifting of the belt upon the variable pulleys 55 takes care of regulating the tension or draw between the printing cylinder i5 and the main cans I5. By making the motor 5! driving the main cans as a masteror lead motor, no additional pro visions need be made to take care of variations in speed of the main printing cylinder l5 incident to'ohansingthe engraving roll I! to dinerent I diameters. Accordingly, combination of the synchronous transmitter and receiver, the differential regulator and the system of variable pulleys 66 give complete speed control over the lineal speed of the printing cylinder I8 regardless of the diameters of the engraving rolls H.

The dancer roll rheostat I4 is arranged to govcm the speed of the pair of second pull rolls I3 withdrawing the material from the scray device, and similarly the dancer roll rheostat 52 is arranged to govern the speed of the motor 55 driving the back grey cans 34. The terms synchronous transmitter and synchronous receiver as used herein are applied to a condition where two slip ring motors of the same number of poles have their primaries connected to the same source of alternating current power and have their secondaries interconnected in the proper phase relation, so that any movement of the rotor of one will result in an exact proportional movement of the rotor of the other. The one which has its rotor moved by an outside force is the synchronous transmitter and the one which has its rotor to electrically follow the motion of the former is the synchronous receiver.

With reference to Figure 2 of the drawings, which is a single line representation showing diagrammatically the electrical control system, the armature oi the main driving motor 54 is arranged to be selectively energized from either a main generator 15 or a threading generator 11. An auxiliary generator I8 is arranged to electrically energize the armature of the motors 5I, 52, 53, 55, 56, 51, and 58. The armature of a buck-and-boost generator 18 is connected in series with the armatures of the motors 5| and 52, which drives respectively the first and second pairs of pull rolls I I and I3 and the armature of a buck-and-boost generator 80 is connected in series with the armatures of the motors 55 and 55 which drive respectively the grey back earns 34 and the batcher device 40. An exciter 8I supplies field excitation to the several fields of the various motors and generators as well as the control relays shown in block form, through the line conductors I33 and I34. The main generator 16, the auxiliary generator I8 and the exciter 8I are driven through mechanical means by an alternating current motor 82 which is energized from an alternating current supply source 84 upon the closing of a contactor 85. The threading generator 11 and the two buck-and-boost generators I9 and 80 are driven through mechanical means by an alternating current motor 88.

which is energized from the alternating current supply source 84 upon the closing of the contactor 85. The primary of the synchronous transmitter 58.and of the synchronous receiver 5! are energized through the three alternating current conductors 81. The secondary of the synchronous transmitter 59 and of the synchronous receiver 62 are connected together by the three wires identified by the reference character 88.

Inasmuch as Figure 2 is a diagrammatic singleline drawing of the electrical system, we have placed the fields for the various motors and generators in substantially a vertical line below therespective motors and generators. In accordance with this plan, the field for the main generator I5 is indicated by the reference character 9| and the field for the main motor 54 is designated by the reference character 85, the field 8| for the main generator being located above the field 95 for main motor 54 because the main generator 15 is located above the main motor 54. As illustrated, the field ii of the main generator is governed by four resistors 54, 42, 93, and 94. The field 95 of the main motor 54 is governed by two resistors 55 and 85. The variable resistors 54 and 55 are governed by the differential regulator 55 so that the speed of the main motor 54 is varied in accordance with two different conditions; namely, the voltage of the main generator I6 incident to variations of the field excitation of the main generator I5 and of the field excitation v of the motor 54. The variable resistors 64 and 55 are arranged such that at relatively low speeds the voltage of the main generator 15 is low and the field excitation of the motor 54 is high and such that at relatively high speed the voltage of the main generator 15 is relatively high and the field excitation of the motor 54 is relatively low. The variable resistor 84 in the field SI of the main generator I6 is governer by a motor operated rheostat I31 which is set into operation by the actuation of the closing of the run fast relay I50 and circuits as shown by the block diagram.

The actuation of the motor actuated rheostat I31 operates a rack and pinion drive I30 which, as illustrated by the double dotted lines I39, actuates the variable resistor 04 to vary the field excitation of the main generator 16 and thus the generated voltage thereof which varies the speed of the main motor 54.

The field for the threading generator I1 is designated by the reference character 91 and is placed substantially vertically .under the threading generator in Figure 2. The field 91 is governed by two adjustable resistors 98 and 99 and a variable resistor I00. As illustrated, the variable resistor I00 is governed by the motor operated rheostat I31, so that the voltage generated by the threading generator 11 is governed by the actuation of the motor operated rheostat I51. The field for the motor 5I driving the first pair of pull rolls I I is designated by the reference character I08 and the excitation thereof is controlled by an adjustable rheostat I00. The field for the buck-and-boost generator 18 is identified by the reference character I I0 and is governed by a vari-j resistor I and the variable resistor II2 are connected by two dash lines, indicated by the refererence character I4 which means that these two variable resistors are controlled by the dancer roll rheostat I4 over which the cloth passes upon leaving the second pair of pull rolls I5. Accordingly, movement of the dancer roll rheostat l4 not only changes the field excitation of the motor 52 to vary its speed but also varies the voltage generated by the buck-and-booster generator 15 to vary the voltage impressed upon the motor 52 and thus its speed. That is to say, the speal of the motor 52 is responsive to its own variable field excitation as well as to the variable voltage generated by the buck-and-boost generator 15, which modifies the voltage of the auxiliary generator II which is impressed upon the motor 52. When the arrow on the resistor I05 coincides with the middle point I40, no current flows through the field of the buck-and-boost generator 18 and thus no voltage is generated to modify the voltage of the auxiliary generator 18 impressed upon the motor 52. When the dancer roll rheostate 54 moves the arrow below the point I48, current fiows through the field winding of the buck-and-boost generator I8 in such direction as to increase the voltage of the buck-and-boost generator I9 to impress an additional voltage upon the armature of the motor 52 to increase its speed, and at the sametime the dancer roll rheostat I4 increases the resistanceof the resistor H2 in the field III of the motor 52 to make the motor further increase in speed. When the dancer roll rheostat I4 moves the arrow above the point I40 upon resistor I05, the current in the field of the also by the voltage impressed thereon as modi-' fied by the buck-and-boost generator I9; The variation of the buck-and-boost generator voltage is also impressed upon the motor 5i which varies the speed ofthe first pair of pull rolls II in accordance with the operation of the dancer roll rheostat I4.

The field for the auxiliary generator-18 is designated by the reference character H3 and the excitation thereof is governed by an adjustable resistor II 4, a variable resistor H5, and two adjustable resistors H6 and iii. As illustrated, the variable resistor H5 is actuated by the motor op erated rheostat i3? so that the voltage of the auxiliary generator I8 is varied to govern the speed of operation of the motors 5!, 52, 53, 55, 56, 51 and 58.

The field for the motor 53 connected to the tension rolls i5 is designated by the reference character H8 and the excitation thereof is gov-- erned by an adjustable rheostat i la and 2 I 'I. The field for the buck-and-boost generatorBO is identiiied by the reference character 62% and the excitation thereof is governed by a variable resistance IZI. The field for the motor 55 driving the grey back cans 36 is identified by the reference character I22 and the excitation thereof is governed by a variable rheostat ifii. The two variable resistors I III and I23 are diagrammatically connected together by two dash lines 32 which indicate that these two variable resistors are governed by the dancer roll rheostat 32 as shown on Figure 1 over which the back grey passes before entering the back grey cans 3d. The operation of the dancer roll rheostat 32 upon the re sistors I2I and I23 is the same as that described for the operation of the dancer roll rheostat I4 the excitation thereof is governed by the adjustable resistance I30. The field for the exciter 8|" is identified by the reference character iii and the excitation thereof is governed by the adjust-.

able resistor I 32. A fixed resistor I02 is in series with the armatureof the motor ii, an adjustable resistor I03 is in series with the armature of the motor 53 and a fixed resistor I04 is in series with the armature of the motor 56.

The operatorthreads the machine by either running it at a low speed of approximately 10 yards per minute by setting up a "run slow condition or operating a jogging circuit. After the machine is threaded with the cloth to be printed, the machine may then be operated under a "run fast condition. In Figure 2 of the diagrammatic drawings, the block indicated by the reference character I48 designates the jog push button, the

upon the resistors I05 and i it. That is to say, the

speed of the motor is not only varied by the change in its field excitation but is also. varied by the voltage impressed upon its armature, as modified by the buck-and-boost generator 80. The motor 56 which drives the batcher device It is also varied by the change in voltage as affected by the buck-and-boost generator 80 in order that the batcher device 40 may wind up the material as fast as it is delivered to it, as governed by the dancer roll rheos'tat 32. The field for the motor 58 driving the .batcher device 40 is identified by the reference character I24 and the excitation thereof is governed by the adjustable resistor I 25.

The field for the motor 51 driving the main cans I I9 is identified by the reference character I28 and block indicated by the reference character I49 designates the run slow push button, and the block indicated by the reference character I50 designates the run fast push button.

In explaining the operation of our electrical system, let it be assumed that the "run slow push button I49 is operated. In order that the run slow push button I49 may be operative it is necessary, that current from the conductor I33, as

supplied from the exciter 66 first flow through a relay Hi5 and a rapid-stop push button indicated by the reference character I 41.. The rapid stop push button it? is normally closed, so that it need not be operated to establish the run slow condiditlon. The relay M5, however, is controlled as indicated by the lead line hit from the contactor 88 that governs the energization of the alternating current motor 83. That is to say, the relay I45 is not energized until the contactor 86 is closed which means that the synchronous transmitter 59 and the synchronous receiver 82 are first electrically energized to keep the printing cylinder 26 in synchrony with the main cans it before the driving motors are set in operation. The relay Mi; also insures that the run slow condition cannot be put into operation until the threading generator I1, and the buclr-and-boost generators iii and are in running operation. The relay M5 having been closed and the rapid stop push button t lt being normally closed, the depression of the run slow push button M9 energizes the relays iSi, M5 and $59. The energization of the rela E55 closes a contactor i5! through the dash-dot lead line I53 and opens a contactor I54 through the dash-dot lead line i 55. As will be explained more in detail with the Figures 8, Land 5, the relay IN is energized only so long as the run slow push button Me is depressed by the operators finger. Therefore, the purpose of closing the contactor I52 is to shunt out the resistor 99 to boost the voltage of the threading generator H which in turn boosts the voltage impressed upon the main starting motor 5 3 to overcome initial starting torque. The purpose of opening the contactor I 5 is likewise to boost the voltage upon the auxiliary generator I8 in order to impress an increased voltage upon the sectional motors having their armature circuits energized by the auxiliary generators "iii. The reason that the contactor I52 need be closed to boost the voltage of the threading generator is that the resistor 99 is in series with the field 9i and the reason that the contactor I56 need be tion of the relay I56 closes a contactor I51 through the dash-dot lead line I58 and connects the armature of the auxiliary generator 18 in circuit relation with the buck-and-boost generators 19 and 80, and the sectional motors I, 52, 53, 55, 56, 51 and 58. The energization of the relay I59 closes a contactor I60 through the dash-dot lead line I6I which connects the armature oi the main driving motor 54 in circuit relation with the threading generator 1.1. The relays I56 and I59 are also electrically connected to the sliding contacts of the motor operated rheostat I31. The sliding contacts of the motor operated rheostat I31 are diagrammatically illustrated, the small block I64 represents the stand-still position of the motor operated rheostat, and the two longer blocks I65 and I66 designate the first and second stage accelerating contacts of the motor operated rheostat. The sliding pointer I61 is actuated up-.

and-down along the contacts by the rack-andpinion drive I38. As illustrated, the relay I56 is electrically connected to the stand-still block I64 through the lead line I68, which means that the relay I56 cannot be energized unless the motor operated rheostat is in its stand-still position, being the position where the pointer I61 coincides with the stand-still block I 64. The relay I59 is connected through the lead line I69 to both the stand-still block I64 and the first stage accelerating block I65. Thus, the relay I59 is energized when the motor-operated rheostat is in its early stages of acceleration as well as in its stand-still position. Accordingly, the threading generator 11 is connected in circuit relation with the main motor 54 through the operation of the relay I59 and the closing of the contactor "I60 only during slow speed operations of the printing machine. The relays I10, I13, I16 and I80 which are arranged in a vertical group are likewise energized in the run slow condition. The relays I16 and I80 are controlled through the lead line I82 through the standstill block I64 of the motor operated rheostat. The relays I16 and I80 are likewise electrically influenced through the lead line I63 by the relay I5I. The relays I and I13 are electrically influenced through the lead line I90 by the run slow push button I49. The energization of the relay I10 closes the contactor I1I through the dash-dot lead line I12. The contactor I1I is normally open so that the resistor 98 is normally in the field of the field 95 to limit the current flowing therethrough when the motor 54 when it is standing still. As soon as the run slow push button I49 is operated, the contactor I1I is closed and full excitation is put upon the field 95 for giving increased starting torque to the main motor 54. The energization of the relay I13 closes the contactor I14 through the dash-dot lead line I15 and completes the establishment of the fields H0 and I for the buck-and-boost generator 19 and 80, respectively. The energization of the relay 516 opens the contactor I11 through the dash-dot lead line I18. The opening of the contactor i1! puts the resistor H9 in the field H8 and enables the operator to operate the variable resistor H9 to make the tension motor 53 operate as a motor to aid in threading the cloth through the tension rolls I5. It is to be noted that the contactor I11 is held open through the relay I16 only so long as the pointer I61 is on the standstill operation during the run block I64 0! the motor operated rheostat. In

will be operated under the last run condition ior production printing, contactor I11 is closed and removes the resistor II9 from the ileid H8 and causes the motor 53 to act as a, drag generator to produce tension upon the cloth preparatory to the cloth entering the printing cylinder I4. Since the motor 53, acts both as a motor for threading purposes and as a generator for tension purposes during printing production, it is referred to in the claims and elsewhere as a dynamo-electric machine. The armature of the motor 53 which is connected to the tension rolls I5 is also provided with an adjustable resistance I03 which may be operated either manually or byan automatic regul'ator to keep the current flowing through the armature of the motor 53 at a constant value to maintain a substantially constant tension on the cloth. The energization of the relay I closes a contactor I'8I through the dash-dot lead line I62 and shorts out the variable resistance of the diiferential regulator and establishes a strong excitation upon the field 95 for the main motor 54 during the run slow condition.

The closing of a snap switch I83 connects the motor 55 that drives the back grey cans 34 in circuit relation with the auxiliary generator 18 so that the back grey cans 34 may be started at the same time as the other elements of the machine are started. The closing of the snap switch I83 energizes a relay I84 which closes a contactor I89 through the lead line I86. The relay I84 is electrically connected through the lead line I85 to. the stand-still block I64 of the motor operated rheostat which means that'the motor 55 driving the back grey cans 34 can only be brought into slow condition for the threading ot the cloth and not during the run fast condition which is for printing operation. In addition, the energization of the relay I84 closes a contactor I88 to energize the field I22 for the motor 55 and opens a contactor I81 and removes the resistor I26 from the field I22. In stopping the motor 55'the contactor I88 is opened and the contactor I81 is closed, so that the voltage set up in the field I22 may be discharged through the resistor I26.

The closing of a snap switch I92 establishes the armature circuit for bringing in the motor 56 which drives the batcher device 40, so that it may be started with the other elements 01 the entire machine. The closing of the switch I92 energizes a relay I93 which through the dashdot line I 95 opens the contact I96, closes the contact I91 and I98. The closing of the contact I08 connects the armature of the motor 56 in circuit relation with the auxiliary generator 18 so that the motor 56 may be started along with the rest oi! the sectional motors. The closing of the contactor I91 establishes the circuit for the field I24 and the opening of the contactor I96 removes the resistor I26 from the field I24. In stopping the motor 56, the contact I91 opens and the contact I86 closes which connects the field I24 in series with the resistance I26 to discharge the field I24. The relay I93 is also electrically con nected through the lead line I94 to the stand-still block I64 of the motor operated rheostat which means that the motor 55 cannot be connected in circuit relation with the armature of the auxiliary generator 18 unless the equipment is under the rim slow condition.

A resistor I04 is in series with the armature of the motor 56 so that as the grey back winds up on the batcher device 40 and the diameter oi the aaraus batcher reel becomes larger, the speed of themotor gradually decreases.

Inasmuch as the cloth accumulates upon the scray device I2, the motor which drives the first pair of pull rolls II is designed to be con- 5 trolled either independently of the other motors or in unison with them. Thus, the depressing 01 a start button I90 energizes a relay 2I0 which through the dash-dot line 2I Icloses the contactor 2I2 to connect the armature of the motor 5I in circuit relation with the auxiliary generator 16 and the buck-and-boost generator 10. The energization of the relay 2I0 operates a relay 2I2 which through the dash-dot line 2 I 4 shortly closes the contactor 2 I5 and shunts out'the resistor I02. The relay 2I3 is arranged to ve a delayed pickup, so that the resistor I02 is in the armature circuit of the motor 5i only momentarily during the starting of the motor, and just as soon as the relay 2i: picks up, after the short time delay, the 20 contactor 2I5 is closed to shunt the resistor I02 and the motor then operates at normal condition. The purpose of the resistor I02 and the time delay action of the contactor 2I5 is to give smoother starting to the motor 5| in unwinding the cloth from the supply reel I 0.

Summarizing, under the condition of the run slow push button I40 being depressed, the main motor 54 is energized from the threading generator' 1.1, the motor 5| which drlves'the first pull rolls II is energized and operating provided the start push button I9! is pressed, the motor 52 which operates the second set of pull rolls I3 is operating, the motor ordynamo-electric 53 which is connected to the tension rolls I5 is operating, 3

the motor 65 which drives the back grey cans 34 may be made to operate upon the closing of the snap switch I86, the motor 56 which drives the batcher device may be made to operate by closing the snap switch I92, the motor 51 which drives 40 the main cans I8 is operating, and the motor 50 which drives the folding rolls I9 is operating.

After the machine is threaded and in condition for normal printing operation, the operator then increases the speed ofthe machine by depressing the run fast push button I50. The essential thing that happens when the run fast push button I is depressed is that the relay 231 is brought into operation through the lead line HI and that the motor operated rheostat I31 is 50 connected to operate, as indicated iby.the lead line 220 and the sliding pointer I61 begins to move up along the sliding accelerating contacts I65 and I 66 and breaks the circuit with the standstill block I64. As shown by the lead line 222, the circuit for operating the relay 23I is not completed until the pointer I61 engages the accelerating block I66. Also. upon the operation of the fast run push button, the relays I16 and I00 become de-energized just as soon as the slidingpointer I61 breaks the circuit with the stand- ,still block I64. The deenergizstion of the relay I00 opens the contactor I6I and inserts the varig able resistance 65 in the field 96 or the main-mo tor. so that the field excitation of the main 6 \e g block '66 indicates that this circuit is motor may now be governed by the diil'erential regulator 63. The de-energization of-the relay I16 closes the contact I11 and shunts the resistor I I0 from the field, I I0 and causes the motor or dynamo-electric connected "to the tension rolls I6 to operate as a direct generator to produce tension upon the cloth being fed to the main a printing cylinder I6. Just as soon as the sliding Pointer I61 en the first accelerating block & rouitigis'iestablished for energizing a relay 7 226 through the lead line 224. Energization of the relay 222 closes the contactor 226 through the dash dot lead line 220. The closing of the contactor 226 connects the two relays. .221 and 220 between the threading generator 11 and the main generator 16,130 that the relays 221 and 228 operate upon the differential voltage between the two generators. In practice the two relays 221 and 220 are such that they open when a-diil'erential' voltage of more than 5 volts exists across their coils and such that they close when the diflerential voltage across their coils is less than 5 volts. As illustrated, the two relays 221 and 220 are electrically connected to the relays I69 and 20I through the dash-dot lines 226 and 220. The relay 2, when energized, is arranged to close the contactor 262 through the dash-dot line 232. Thus, the relays I50 and 23I may be characterized as transier relays for transferring the armature of the main motor 54 from the threading generator 11 to the main generator 16 forfast' run condition. The action of the transfer from the threading generator 11 to the main generator 16. may be described as follows: Upon the depression of the fast run push button I 50, the motor operated rheostat I61 is put in operation and the sliding pointer I61 begins to move up and make engagement with the accelerating contact blocks I65 and l60.' Just as soon as the starting point I61 engages the block I65 a circuit is established for energizing the relay 222 which in turn closes the contact 225 for introducing the relays 221 and 1 220 between the threading generator 11 and the main generator 16. In the meantime, the pointer 5 I61 is still moving up and when it passes from the block I65 to the block I66 the relay I50 thereby becomes de-energized which in turn opens the contactor I60 and removes the threading generator 11 from circuit relation with the main motor 54. By the time that the sliding pointer I61 reaches the gap betweenthe blocks I65 and I66, the voltage of the threading generator 11 and the voltage of the main generator 16 are so adjusted that the diiference in the voltages therebetween is less than 5 volts so that the relays 221 and 228 close to energize the relay 23I, since this relay makes electrical contact only with the upper accelerating block I66 of the voltage regulator. In other words, the relay 22I will not become energized unless the differential voltage upon the relays 221 and 228 is less than 5 volts even though the relay 23I is connected in circuit relation with the ,upp r accelerating block I66 through the sliding pointer I61, The purpose of the relays 221 and 228 is to prevent too large a currentdisturbance as the motor I54 is transferred from the threading generator 11 to the main generator 16. In actual, practice, the transfer from the threading generator 11 to the main generator" may take place in the neighborhood of 35 volts which means that above 35 volts the main motor 54 is operated from the main generator which carries the voltage up to normal operation in'the neighborhood of 230 to 240 volts. The dot-line 2I6 leading from the lead line 224 and the acceldisrupted after the pointer I61 passes beyond the dot-line 2" to de-energize the relay 223 and re move the relays 221 and 220 from the dilferential circuit between the threading generator 11 and the main generator 16, so that the relays 221 and 220 are not exposed to high diiferential voltages at high speeds. The speed to which the main motor attains under the fast run condition is determined by the setting of the motor opergenerator, as well as by ated rheostat I31 which varies the field excitation of the field SI for the main generator 15. The speed of the remaining sectional motors which are connected to receive energization from the auxiliary generator 15 is determined .by the field excitation of the field H for the auxiliary generator 18 through the variable movement of the resistor II5 as operated by the motor operated rheostat. It is to be observed that the motor 5| driving the first pair of pull rolls II can be started and stopped under the run fast condition, whereas the motors 55 and driving the grey back cans 34 and the batcher" device 45 cannot be started or stopped under the run fast condition, because relays I54 and I53 which control the armature circuit for the motors 55 and 55 are de-energized just as soon as the sliding pointer I61 moves from the stationary stand still block I64 upon the motor operated rheostat I31.

When the operator desires to stop the entire machine after it has been operating in the run fast position. he first depresses the run slow button I49 which connects the motor operated rheostat I31, only for deceleratingpurposes, in circuit relation with the run slow push button I45 through the lead line 234. Therefore, the motor operated rheostat begins operating in a reverse direction and the sliding contact I51 moves downwardly. When it passes from the block I55 to the block I65, the transition takes place for transferring the main motor 54 from the main generator 15 back to the threading generator 11. Upon the deceleration of the main motor 54, the relays 221 and 225 function to prevent too large a current disturbance upon the armature of the motor 54 during the transition period by operating the relays 23I and I59 such that a differential voltage of less than 5 volts exists between the threading generator 11 and the main generator 15 upon the transition taking place. In the run slow position the motor operated rheostat I51 continues to operate until the sliding pointer I51 reaches the stand-still block I54 which means that the speed of the machine has been reduced to approximately 10 yards per minute after which the opererator stops the entire machine by depressing the push button I41 which de-energizes all of the relays. The relay I41 is normally referred to as a rapid stop push button because, regardless of the speed under which the machine is operating, in cases of emergency, the operator can depress this button and completely stop our system of control. As shown, the rapid stop button I41 through lines 255 and 254 causes the motor .operated rheostat to operate in a reverse direction extremely fast and efl'ect a very rapid stop. The method of stopping the entire equipment by depressing the rapid stop pu h button I41 is resorted to only in the case of emergency. The normal method of stopping the equipment is to first depress the run slow button to reduce the speed to approximately 10 yards per minute and then depress the rapid stop button I41 which does not cause a rapid deceleration of the motor oper ated rheostat since the motor operated rheostat has already been actuated to its stand-still position,

In our system of control, we use separate generators for the main motor 54 and the remaining motors 5I, 52, 55,55,55, 51 and 55. Inthis manner the speed of the main motor 54 may be controlled by the voltage impressed thereon from the main the change in the field excitation of the motor 54. Also, the load on the printing machine I5 sometimes may be light and aaraus sometimes may be heavy and for this reason by using separate generators the voltage fluctuation in the main generator 16 is separate from the voltage generated in the auxiliary generator 15, so that the motors M, 52, 55, 55, 56, 51 and are independent of any load conditions upon the printing cylinder I5. Also, the differential regulator 53 has no effect upon the voltages impressed upon the motors 5|, 52, 55, 55, 55, 51 and 55. The employment of the threading generator 11 and main generator 15 to energize the main motor 54 also gives active control at threading speed as well as at high speed.

In the event that the operator prefers to thread the machine by jogging instead of running the machine under the run slow condition, he may depress the jog button I48 to energize the relays I55 and I59 for closing the contactors I51 and I55, respectively. The depression of the job button I45 also establishes circuits for energizing the relays I10 and I13 which closes the contactor Ill and I14. The relays I15 and I55 are also energized through the standstill position I54 on the motor operated rheostat which means that the contactor I11 is open and the contactor III is closed. The jogging button I45 is associated with a time delay interrupting circuit designated by the reference character 235, such that even though the operator should depress the jog button I48 for a long period of time the jogging is automatically interrupted at a pre-determined time interval. Therefore, regardless of whether or not the operator depresses the button I45 only momentarily, or for a. long period of time, the effect of the Jogging operation is to give a. time limit to each jog operation.

The complete circuit for our control system is shown in Figures 2, 3 and 4, in which corresponding reference characters represent the same parts as illustrated on the diagrammaflc drawing in Figure 2. The alternating current motor 52 is set into operation by closing the switch 251 which actuates the contactor 55 for supplying alternating current thereto. The alternating current motor 53 is set in operation by closing the switch 235 actuating the contactor 55 which supplies alternating current thereto. The closing of the extra contactor I45, as the alternating current motor 55 is energized, establishes a circuit for energizing a relay 235, through the conductors 24I and 242. The closing of the contact 241 of the relay 238 establishes a circuit for energizing a relay 245 through the conductors 245. The closing of the contacts 244 and 245 of the relay 233 and the closing of the contact 245 of I the relay 245 connects the primaries of the synchronous transmitter 55 and synchronous receiver 52 in circuitrelation with the alternating current supply 84 through conductors 51. In accordance with the above electrical arrangement, the synchronous transmitter 55 and synchronous receiver 52 are electrically energized to keep the lineal speed of the printing cylinder I5 in synchrony with the linear speed of the main cans I8 just as soon as the alternating current motor 53 is energized for operation.

In describing the diagram in Figures 3, 4 and 5. the armature circuits for the sectionalized motors will be traced first. The circuit for energizing the armature of the motor 5| may be traced; beginning with conductor 25I of the auxiliary generator 15 current flows through the contact I51 of the relay I55, the conductors 252, 255, 254, the armature of the buck-and-boost generator 15, the conductors 255 and 255, the armature of the motor I and then through a conductor 251, the contact 2I2 of the relay 2I0, the contact 2I5 of the relay 2I3 and the conductors 258, 259 and 260 to the opposite side of the armature of the auxiliary generator 18. The circuit for energizing the armature of the motor 52 may be traced as follows beginning with the conductor 25I of the auxiliary generator 18 current flows through the contact I51 of the relay I56, conductors 252, 253, 254 generator 59, after which current flows through conductors 255 and 263 to the armature of the motor 52, after which current flows through the conductors 264, 258, 259 to the conductor 260 on the opposite side of the auxiliary generator 18. The circuit for energizing the armature of the motor 53 may be traced as follows; beginning with conductor 25I of the auxiliary generator 18 current flows through the contactor I51 of the relay I56, conductors 252 and 265 to the armature of the motor 53, the system of resistors I03 and conductors 266, 258, 259 to the conductor 260 on the opposite side of the auxiliary generator 18. The circuit for energizing the armature of the motor 55 may be traced as follows; beginningwith the conductor 25I of the auxiliary generator 18 current flows through the contactor I51 of the relay I56, conductors 252, 253, 254, 261 to the armature of the buck-and-boost generator 80, conductors 268 and 269 to the armature of the motor 55, conductor 210, the contactor I89 oi the relay I84, and conductors 21I, 258, 259 to the conductor 260 on the opposite side of the auxiliary generator 18. The circuit for energizing the I armature of the motor 56 may be traced; beginning with the conductor 25I of the auxiliary generator 18 current fiows through the contactor I51 of the relay I56, conductors 252, 253, 254, 261 to the armature of the buck-and-boost generator 80, conductors 268 and 215 to the armature of the motor 56, a conductor 51 may be traced; ning with the conductor 25I of the auxiliary generator 18 current flows through the contactor I51 of the relay I56, conductors 252, 253, 218 to the armature of the motor 51, and conductors 219, 258 and 259 to the conductor 260 on the opposite side of the auxiliary generator 18. The circuit for energizing the armature of the motor 58 may be described as follows; beginning with the conductor 25I of the auxiliary generator 18 current flows through the contactor I51 and the relay I 56, conductors 252 and 280 to the armature of the motor 58, and conductor 28I to the conductor 250 on the opposite side of the auxiliary generator 18.

The circuit for energizing the armature of the main motor 54 from the threading generator 11 may be traced; beginning with the conductor 282 current flows through conductor 283 to the armature of the motor 54, conductors 284 and 285 to the contactor I60 oi the relay I59, conductors 286 and 281 to the conductor 288 of the threading generator 11. The circuit for energizing the armature of the main motor 54 when energized from the main generator 16 may be traced; beginning with the conductor 289 current flows through conductors 290 and 283 to the armature of the motor 54, conductors 284 and 29 I, the contactor 233 of the relay 23 I, conductors 292 and 293 to the conductor 294 on the opposite side of the main generator 16. Upon the deenergization of the main driving motor 54, a

through the armature of the buck-and-boost.

on the opposite side v various motors and dynamic breaking circuit is established through the armature of the main motor 54 which may be traced as follows, beginning with the conductor 284 on one side of the armature of the main motor 54 dynamic breaking current flows through conductor 298, the conductor 299, conductor 300, a resistor 30I, and conductor 302, 290, 283 to the opposite side of the armature of the main motor 54. Also, when the armatures of the motors 5|, 52, 53, 55, 56, 51 and 58 are de-energized a dynamic breaking circuit is which extends from opposite sides of their common connection; namely, from conductor 252 which is common to one side of the motors 52, 53, 55, 56, 51 and 58 through a resistor 303, conductor 304, contactor 30501 the relay 301, and conductor 306 which is connected to the conductors 259 and 258 which are common to motors 5|, 52, 53, 55, 56, 51 and 58.

The circuit for energizing the fields for the generators will be described next. All of the fields are energized from the exciter 8|. One side of the exciter has a common conductor 309 which extends vertically downwardly on Figure 3, then to the right along the bottom of Figure 3 over to the lower righthand edge of Figure 4 and then vertically upwardly'towards the top of the Figure 4. The other side of the exciter 8I is connected to a common conductor 3I0 which extends across the top of. Figures 3, 4 and 5 and then down the right hand side of Figure 5. The circuit for energizing the field I 3| of the exciter extends from the common conductor 309 through conductor 3 to the field I3I and the adjustable resistor I32 to the common conductor 3I0. The circuit for energizing the field I08 for the motor 5| may be traced; beginning with the common conductor 309 through conductors 3I2, 3| 3, 3, the field I08, the adjustable resistor I09, conductors 3I5, 3I6, 3I1, 3I8, 3I9 and '320, MI, 322 and 323 to the other common conductor 3I0. The circuit for energizing the field III of the motor 52 may be traced; beginning with the common conductor 309 through conductor 3I2 and 308, the field III of the motor 52, conductors 328 and 325, the potentiometer rheostat resistor H2, and conductor 3I1, 3I6, 3I9, 320, 32I, 322 and 323 to the common conductor 3I0. The pointer 33I for the potentiometer rheostat H2 is connected by a conductor 326 over to the conductor 325 which is connected to the beginning of the potentiometer resistor H2. Th potentiometer rheostat II 2 comprises part of the dancer roll rheostat I4 as shown on Figures 1 and 2 of the drawings. The circuit for energizing the field II 8 of the motor 53 may be traced as follows; beginning' with the common conductor 309 current flows through conductors 3I2, 3I3, 332, the field I I8 of the motor 53, the adjustable resistor 2I1, conductor 333, adjustable resistor II9, conductors 334, 322 and 323 to the common conductor 3I0. The variable resistor 3I9 is shunted by the contactor is open whenthe motor 53, or the dynamo-electric machine 53, is operating as a motor for threading purposes so that the operator may adjust the rheostat H9 to control the speed for threading purposes. For normalprinting operation, the contactor I11 is closed and the excitation oi'the field H8 is governed by the setting of the resistor 2I1.

The circuit for energizing the field of the main driving motor 54 may be traced as follows; beginning with the common conductor 309 cur- I11 of the relay I16. The contactor I11.

set up for these motors the other side of the rent flows through conductors 335 and 336, the field 95, resistor 96, conductors 331 and 330. the variable resistor 65 of the differential regulator, conductors 339, 346, 362, 340, 34| and 342 to the other common conductor 3I0. The relay I10 is energized in' the slow run position so that the contactor 1| shunts the resistor 36 in the slow run or jogging position to put full field upon the motor 54. The resistor 65 of the differential regulator is likewise shunted by the contactor |8| of the relay I80 during the run slow condition or the jogging condition through conductors 338 and 344, the contactor |8|, conductors 345, 346 and conductors 339. The circuit for energizing the field I 22 of the motor 55 may be traced from the common conductor 309, as appearin on the bottom of Figure 4 through conductor 341 the potentiometer resistor I23, conductor 348, the contactor I88 of the relay I84. the field I22, conductors 349, 3|6, 3|1, 3|8. 3|9, 320. 32I, 322 and 323 to the opposite common conductor 3I0. The potentiometer resistor I23 comprises part of the dancer roll rheostat 32 as shown in Figures -1 and 2 of the drawings; The circuit for energizing the field I24 of the motor 56 may be traced as follows; beginning with the common conductor 309 current flows through conductors 335, 352, 353. the ad ustable resistor I25. conductor 351. contactor |31. conductors 354 and 355, the field |24, and conductors 356, 349, 3|6, 3|1, 3|8, 3|9. 320. 32I, 322 and 323 to the common conductor 3I0. When the relays I84 and I93 are de-energized and the contactors I81 and |96 are closed the fields I22 for the motor 55 and the field I24 for the motor 56 discharges throu h a resistor I26 c nnec ed to conductors 3I6.3|1, 3 8. 3I9, 320, 32I, 323 to the common conductor 3| 0.

The circuit for energizing the field I21 of the motor 5 may be traced from the common conductor 309. as found on the bottom of the Fi ure 3. through conductor 3 0. the field I21. the adiustable resi tor |28. conductor 36I. 346, 362. 3 0. 34| and 342 to the common conductor 3I0. The circuit for energizing the field I29 of the motor 58 may be traced: beginning with the common conductor 303 current flows throu h con uctors 3| l. 363, the field I23. the adjustable resi tor I30. and conductor 364 to the common con uctor 3I0.

The circuit for energizing the field 9| of the main generator 16 is a parallel circuit in which one branch may be traced from the common conductor 309 through conductor 366. the field 9| of the main generator I6, conductor 361, the adjustable resistor 93, conductors 368 to the slide bar 312 of the motor operated rheostat I31, then through the bridge conductor 31| and the resistor 94 to the common conductor 3I0. The other parallel branch, which is electrically connected with the field 3| of the main generator 18. may be traced from the common conductor 303 through conductors 363. the adjustable resistor 92, the variable rheostat 64 o! the differential regulator 63, conductor 310 to the resistance 94 or the motor operated rheostat I31 and to the common conductor 3I0. Therefore, the field 3| of the main generator 16 is controlled by both the resistor 34 of the motor operated rheostat and the resistor 64 of 'the voltage regulator 63.

The circuit for ener izing the field H3 or the auxiliary generator 18 likewise comprises two parallel circuits which may be traced as follows: the first parallel circuit may be traced beginnin with the common conductor 303, through conductor 366, the field H3- of the auxiliary generator 18, conductor 315, adjustable resistor H4, conductor 316 to the slide bar 311 of the motor operated rheostat I31, the bridging conductor 318 and the resistor H5 of the motor operated rheostat to the common conductor 3I0. The other parallel circuit of th field H3 may be traced beginning with the common conductor 303, as found on the vertical right hand edge of the Figure 4, current flows through conductor 313 to the adjustable resistor H6, the adjustable resistor H1, the resistor H5 0! the motor operated rheostat and then to the common conductor 3I0. The circuit for energizing the field 91 of the threading generator 11 may be traced as follows: beginning with the common conductor 309 current fiows through conductor 38I, the field 91, conductor, 383, the adjustable resistor 98, the adjustable resistor 39, conductor 384 to the slide bar 385 of the motor operated rheostat, the resistor I00, the bridging conductor 386, and the slid bar 381 to the common conductor 3I0. The circuit for energizing the field H0 of the buck-and-boost generator 19, which involves a mid-point potentiometer resistance circuit to give a negative and positive excitation to the field H0, may be traced as follows; beginning with the common conductor 303, as found upon the vertical right hand side of Figure 4, current fiows through conductors 389 and 390, the potentiometer resistance I05, conductors 39I, 392, the contactor I14 0! the relay I13, and conductors 393, 320, 32l, 322, and 323 to the common conductor 3I0. The field circuit which shunts the resistance circuit may be traced beginning with the mid-point I40 upon the potentiometer resistor I05 through conductor 334 to the field I I0 then through conductor 335 back to the arm 336 of the potentiometer resistor. As shown on Figure 2, the resistor I05, and the arm 396 of the potentiometer resistor comprise part of the dancer roll rheostat H. The circuit for energizing the field I20 of the buck-and-boost generator also involves a potentiometer resistance circuit shunting the field I20 of the buck-and-boost generator to give both a positive and a negative excitation for giving buckand-boost voltages. The circuit may be described as follows; beginning with the common conductor 309 on .the vertical line on the right hand edge of Figure 3, current flows through conductor 399. the resistance |2|, conductor 392, the contact I14 of the relay I13, and conductors 393', 320. 32I, 322, and 323 to the common conductor 3I0. The shunting field circuit may be traced from the mid-point 338 upon the resistance I2| through conductor 339, the field I20, and conductor 400 back to the arm 40| of the potentiometer resistor. The resistor |2| and the arm 40| comprise part of the dancer roll rheostat 32 as shown as Figure 2 of the drawings.

As previously pointed out, the motor 5| which drives the first pair of pull rolls II is arranged to be started andstopped independently of the control oi the other motors. The relays which govern the starting and stopping of the motor 5| comprise relays 2I0, M3 and 0. Of these relays the relay 0 is energized immediately with the starting of the exciter 3| and the circuit for energizing the relay 4|0 may be described as follows; beginning with the common conductor 309 current flows through conductor 3|2, 3|3, 420, 4, the contactor 4| 5, conductor 4I6, the coil of the relay 4|0, conductors 4I1, 3|8, 3|3, 320,

3I3, 420 and 42!, the start push button I99. the

stop push button-200, conductor M8, the coil'of the relay 2i 0, conductor 4I9, contactor 422 of the relay 4I0, conductor 4E1, 3I8, 3I9, 329, 32!, 322, 323, to the common conductor 3I0. The energization of the relay'2i9 opens the contactor H5 and de-energizes the coil of the relay am. .The de-energization of the coil 4i0 causes the relay M0 to slowly close as this relay is a time closing relay. Upon the closing of the contactor the snap switch I03 which establishes a circuit as follows; beginning'with the common conductor 309 upon the right hand vertical edge of the Figure 4, current flows through conductor 436,

423 of the relay MD a circuit is established for energizing the coil of the relay 2E3 through the contactor 424 of the relay 2 I0 and conductor 425. The energization of the relay 2I3 causes the contactor '2I5 to remove the resistor I02 from the armature circuit. The relay 2! has a self-holding circuit which, when the start push button I99 is depressed and the relay 2I0 is energized, extends from conductor 42! on one side of the stop push button I99 through conductor M3, the closing of the contact 424, and conductor 425 to the other side of the stop push button I99. In

this manner, the motor 5| continues to be ener-.

gized. for operating the first pair of pull rolls II so long as the relay 2! is self-energized through its own contact 424. Themotor 5| may be stopped by depressing the stop button 200 which 'de-engergizes the relay 2I0. Inasmuch as the relay 2I0 is continuously energized through its own holding circuit. a resistor 421 is shunted around the contactor 422 of the relay M0 in order 'to insert resistance in the circuit of the coil of the relay 2I0 upon the de-energization of the relay 0. v

The motors 55 and can onlybe started when the movable part 403 actuated by the rack and pinion drive of the motor operated rheostat I31 is in its standstill position on the left-hand side of the dotted box outline in Figure 5 of the drawings. In the standstill position, the relays 4Ii and H2 are energized, the relay 4I2 establishing circuits preparatoryto starting the motors and 50 and both relays establishing circuits for starting the equipment under jogging, run slow and run fast conditions. The circuit for energizing the relays 4H and 2 maybe traced ,as follows: beginning with the common conductor 309 on Figure 4 of the drawings upon the vertical line, current flows through conductor 430 to the slide bar-,43I of the motor operated rheostat. From the slide bar 43I- current .passes through the bridging conductor 432 to the standstill point contact .433 from which current flows through conductor 434, the winding of the relays 2 and I and the conductor 435 to the common conductor 3I0. 'Upon the'movable part 403 of the motor operated rheostat leaving the standstill conductor point 433 the circuit is broken for energizing the relays 4H and H2 and thus the motors 55 and 50 cannot be started except in the standstill position; being the condition for run' slow'or jogging. The starting circuit for the motor I5 is completed by the operation of the relay I93. The relay I04 may be energized by closing I84 and the motor 55 the contactor 431 of the relay 2, conductor 438, the snap switch I83, the winding of the relay I84, conductors 439, 440, Nil, 346, 362, 340, MI, and 342 to the common conductor 3I0. When the relay I84 is energized it continues to be energized by its own holding circuit which means that the relay 4I2 has no further control over the relay when once started, That is to say, when once the motor 55 is started it can continue to operate even though the movable part 483 of the motor operated rheostat in Figure 5 moves to the right and breaks the circuit at the standstill contact point 433. The self holding circuit for the relay I84 may be traced as follows; beginning with the common conductor 309 upon the lefthand vertical line in Figure 3 current flows through conductor 335, 352, 444, the contactor 44! of the relay I84, the winding of the relay I84 and conductors 439, 440, 30!, 345, 362, 344?, 34! and 342 to the common conductor 3W. Upon the closing of the snap switch E92 a circuit is established for energizing the relay i93 which may be traced as follows; beginning with the common conductor 309 on Figure 4, the right hand vertical linefcurrent flows through conductor 445, the contactor 446 of the relay 4I2, conductor 441 vto the snap switch I92, the coil of the relay I93, the conductors 440, 36!, 345, 362. 440, Ml. arid 442 to the common conductor 3I 0. When the relay I93 is energized, a self holding circuit is established through the contactor 448, which circuit may be described as follows; beginning with the common conductor 309 upon Figure 3 current flows through the conductors 335, 352, 444, the contactor 448, the coil of the relay I93, conductors 440, 36I, 346, 362, 340, HI and 342 to the common conductor 3| 0. Therefore, the motor 56 can be started only when the relay M2 is energized. being governed by the standstill position of the motor operated rheostat I31, but just as soon as the motor 55 is once started by the closing of the relay I93 it may continue to operate even though the relay 4I2 be de-energized.

The generators and the sectionalized motors are set in the run slow operation by depressing the run slow push button I49 which is located on Figure 5 of the drawings and comprises an auxiliary contactor 540. The conditioning of the generators and motors for the run slow speed for threadin and matching purposes, is dependent upon the energization of an overload relay 45I which is governedv by overload devices indicated by the block 454 and the contact 455 of the starter for the alternating current motor 03 that drives the threading generator and the two buck-andthe overload relay 45I energized, the depression of the run slow push button I49 establishes a circuit for energizing the following relays; name- 1y, I5I, I13, I56, I59, I10, I80, and I16. These relays are the relays shown in the diagram of Figure 2 and are adapted to control the armatures and fields of the motors and generators.

The depression of the run slowpush button I49 also energizes the relays 301, 450, 452 and 453. These latter four relays are not shown on the diagram in Figure 2 for the reason that they may be designated as advance set up relays and do not directly control or govern the armatures and fields oi the motors and generators. The circuit for energizing the relay II may be described as follows; beginning with the starting point 46I on Figure 5, which is a point on the energized conductor 456 and governed by the contactor 455 on the starter for the alternating current motor 83, current flows through the rapid stop push buttons I41, conductor 462, the contractor 463 of the relay M I which is energized because the motor operated rheostat I31 is in the standstill position, conductors 464 and 465 to the run slow push button I49, conductors 466 and 461, the winding of the relay I5I; the conductor 468, the contactor 469 of the relay 4I2,which is energized because the motor operated rheostat is in its standstill position, and conductor 34I and 342 to the common conductor BID. The energization of the relay I5I closes the contactor I52 for shunting the resistor 99 and opens the contact I54 for including the resistor H1 in the circuit, which as explained hereinbeiore is arranged to boost the voltage of the threading generator 11 and the auxiliary generator 18 during the initial starting of the equipment so long as the run slow push button I49 is depressed. That is to say, the momentary boost in voltage upon the threading generator 11 and the auxiliary generator 18 is only effective so long as the operator is depressing the run slow push button I49.

The circuit for energizing the relays 450 and 452 upon depressing the run slow push button I49 may be traced as follows; beginning with the energized depressed run slow push button I43 current flows through conductors 41I and 412, the coil of the relay 452, conductor 413, the coil of the relay 450, the conductors 414 and 415, the contactor 416 of the relay 45I, and conductor 411 over to the contactor 418 on the relay 240 on Figure 3, conductor 419, 480, 340, MI and 342 to the common conductor 3I0. The energization of the relay 452 establishes a holding circuit through the closing of the contactor 48I to bridge the run slow push button I49, so that the operator need no longer hold the run slow push button depressed to keep the equipment in operation. The holding circuit extends from the rapid stop push button I41 through conductor 482, contactor 48I and conductor 41I. The reason that two rapid stop push buttons are shown on the drawing is thatthe equipment is rather extensive and covers a large area and for this reason several rapid stop push buttons are set about upon the machine in convenient locations for giving quick access to the operator in the event that an emergency arises to stop the equipment quickly. Upon the energization of the relay 452, a circuit is established for energizing the relay 453, which circuit may be traced beginning with the common conductor 303 of Figure 4 current flows through conductor 430, the slide bar 43I of the motor operated rheostat, conductor 486, contactor 481 of the relay 452, a fixed resistor 489, the winding of the relay 453 and conductor 488 to the common conductor 3 I 0. The energization of the relay 453 sets up a circuit for energizing the relays 301, I13 and I80, The circuit for energizing these relays may be traced from the common conductor of Figure 3 through conductors 3I2, 3I3, 420, H3, H4, 490, the winding 01' the relay 301, conductor 49!, the winding or 74 the relay I13, conductors 493, 435, 496, 491, 458, contactor 433 of the relay 453 and conductor 500 to the common conductor 3 I 0. The circuit for energizing the relay I10 may be traced from the common conductor 309 along the bottom of Figure 3 to conductor 50I, the winding of relay I10, conductors 502, 491, and 438, contactor 499 and conductor 500 to the common conductor 3I0. The energization of the relay 301 through the opening of the contactor 305 removes the dynamic breaking circuit upon the motors 5I, 52, 53, 55, 55. 51, and 58, and through the closing of the contactor 503 establishes a circuit for energizing the relays I56, which when the contactor I51 thereof is closed establishes a circuit for connecting the auxiliary generator 18 in circuit relation with the electric motors 5I, 52, 53, 55, 55, 51, and 56. The circuit for energizing the relay I56 may be traced from the common conductor 309 on Figure 3 through conductors 3I2, 3I3, 420, H3, H4 and 505, the coil-of the relay I56, conductor 506, the contactor 503 of the relay 301, conductors 501, 508, 495, 496, 491, and 498, contactor 493 of the relay 453 and conductor 500 to the common conductor 3I0. The energization of the relay I13 by the opening of the contact 299 removes the dynamic breaking circuit upon the motor 54 and by the closing of the contactor 509 establishes a circuit for energizing the relay I59 which, when the contactor I60 thereof is closed, connects the armature of the main driving motor 54 in circuit relation with the threading generator 11. The circuit for energizing the relay I59 may be traced from the common conductor 309 upon Figure 4 from the vertical line of Figure 4 through conductor 430, the slide bar 43I of the motor operated rheostat, the bridging conductors 432 and 5I0 to the contact point 5II upon the motor operated rheostat, conductor 5I2 and 5I3, the winding of the relay I53, conductor 5I4, contactor 5I5 of the relay 23I, which is de-energized until the fast run push button I50 is depressed, conductors 5I6 and 5I1, contactor 5I8 of the energized relay H I, conductors 5I9 and 529, contactor 509 of the relay I13, conductors 52I and 498, contactor 499 and conductor 500 to the common conductor 3I0. When themovable part 483 of the motor operated rheostat I31 is on the standstill position, a circuit is established through the contact 523 of the relay 4 for energizing the relays 480 and I16. The energization of the relay 480 which, when the contactor 48I thereof is closed, removes the differential regulator resistor from the field circuit of the main motor 54. The circuit for energizing the relay 480 may be traced as follows; beginning with the conductor 303 on Figure 4 from the vertical column thereof, current flows through conductors 522, contactor 52-3 of the relay 4, conductors 524 and 525, the windin of the relay I80, and conductors 480, 340, HI, and 342 to the common conductor 3 I0. The circuit for energizing the relay I16 which, when the contactor I11 thereof is open, inserts the variable resistance I I9, in the field circuit I I8 of the dynamo electric machine 53, causing the machine to operate as a motor and enabling the operator to operate the speed of the motor by regulating the adjustable resistor II9, may be traced as follows; beginning with the common conductor 309 on Figure 4 of the vertical column thereof, current flows through the conductor 522, the contactor 523, a resistance 530, the winding of the relay I16 and conductors 334, 322 and 323 to the common conductor 3I0. The contactor 532 on the relay I5I is arranged to be in parallel with the contact 522 the relays 4H and I5I, the relay 4 being ener gized when the motor operated rheostat is in its standstill position and the relay I5! being energized so long as the run slow push button I49 is depressed.

Summarizing, when the runslow push button I49 is depressed and with the overload 45I energized and the contactors for starting the alternating current motors 82 2 nd 83 are closed, the

motors an generators are in condition for running slow for threading or matching up purposes. Under this condition the relays I5I, 450,452, 453, 301, I13, I56, I59, I10, I16 and I80 are energized. After the equipment is running in the run slow condition it may be speeded up for normal operation by depressing the run fast push. button As explained with referenceto Figure 2, the depressing of the run fast push button I 50 establishes a circuit for setting the motor operated rheostat I31 in operation. As the movable part 483 in Figure 5 is actuated to the right by the rack and pinion drive I 38, as driven by the ilot motor 544, circuits are established for energizing the relay 28I which connects the main motor 54 in circuit relation with the main generator 16, and

the relay 223 which connects the two relays 221 and 228 between the threading generators 11 and the main generator 16 in order to govern the transition with a minimum amount of current disturbance upon the main driving motor 54. In the run fast position, the relays ,which were established under the run slow condition are maintained except the relays I5I, I16 and I80, and the relays M I and, 4 I2 which become de-energized just as soon as the movable part 483 leaves the contact point 439 of the standstill position, in which event the contactor 660 of the relay 4| I establishes a circuit in parallel with the contactor 416 of the relay 45!, The circuit extends from the left terminal of the contactor 416 through conductors 41,5 and 659, the contactor 660 of the relay 4H, conductors 6| 2 and 411 to the right terminal of the contactor 416. The opening of the contactor 558 of the tie-energized relay 4H would disrupt the circuit for energizing the relay 459, except for the fact that the contactor 105 v of the relay I59 shunts the contactor 5I8. The shunting circuit extends from the right terminal of the contactor 5I8 through conductor 5I1, 516

, and 106, contactor 105, conductors 101, 6.52, 5I9

to the other terminal of the contactor MB of the relay 4! I. The pilot motor 544 which drives the rack and pinion drive for moving the movable parts 483 of the motor operated'rheostat is governed by the relays 546 and 596. Upon the depressing of the run fast. push button I50, the relay 546 when energized causes the pilot motor 544 to operate in such direction as to cause the rack and pinion drive I38 to move the movable part 483 to the right and the relay 596 when energized is arranged to cause the pilot motor to operate in the reverse direction to move the movable part 483 to the left. Assuming that the relay 546 is energized, the current for operating the armature of the pilot motor 544 may be traced as follows; beginning with conductor 591 upon the ver- 544. As illustrated, the resistor 601 is permanently connected across 'theterminals of the armature 544 whereas the resistor 608 is connected across the terminals of the armature 544 through conductor 609, the contactor 8I0 of the relay 450 which is energized under both the run slow condition and the run fast condition, and conductor SI I, The resistor 601 and 608 tend to limit the speed of the pilot motor 544 when driving the movable part 483 of the motor operated rheostat to the right to gradually increase the speed of the sectional motors. The pilot motor 544 is arranged to be operated in a reverse direction to drive the movable part 483 to the left to slow down'the speed of the motors when the relay 596 is energized and the relay 546 is de-energized. The cir cuit for operating the motor 544 in the reverse direction may be traced as follows; beginning with the vertical common conductors 309 of Figure 4, current flows through conductor 591 and GM, the adjustable resistor 6I5, the contactor 6I6 oi the relay 596, a conductor 602, the armature of the pilot motor 544; conductor 60I, the contactor 6I1 of the relay 596, conductor 605, the field 606 to the common conductor 3I0. Accordingly, when the relay 546 is energized and the relay 596 is de-energized the pilot motor 544 operates in one direction to drive the movable part 483 to the right to increase the speed of the equipment and when the relay 596 is energized and the relay 546 is tie-energized the pilot motor 544 operates in a reverse direction to drive the movable part to the left to decrease the speed of operation. The selective energizing of the relay 546 and 596 are governed by the relay 585, the polarized relay 541 having two windings 559 and 563. The relay 535 is energized upon the depressing of the run fast push button E50 and the energization of the relay 535 governs the excitation of the polarized windings 558 and 5630f the polarized relay 541. The balancing of the energization of the polarized windings 559 and 563 directly govern the selective energization of the relay 546 and 596 for controlling the direction of the running of the pilot motor 544.

.The circuit for energizing the relay 535 upon the closing of the run fast push button 150 may be traced as follows; beginning with the point 46I upon the energized conductor 456, current flows through the stop push buttons I41, conductor 482, the contactor 48I of the energized relay 452, conductor 4H, the auxiliary contactor 540 upon the run slow push button I49, the run fast push button .458, conductor 536, a resistor 531, the Winding of the relay 535, conductor 538, contactor 539 of the relay 54l and conductor 411 to the contactor 418 of the relay 240 on Figure 3 and then through conductors 419, 480, 3 40, 34I and 342 to the common conductor 3 I 0. The energization of the relay 535 closes a contactor 542 I which establishes a holding circuit for the relay 54!, contactor 542 and conductor 535. The closing of the contactors 554 and 555 establish a series of circuits for energizing the polarized winding 559 and 553 of the polarized relay 541 to govern the selective energization of the relays 545 and 549 that determine the direction of the rotation of the pilot motor 544, The circuit for energizing the polarized winding 559 may be traced as r01- lows; beginning with the vertical common conductor 309 on Figure 4 current flows through conductor 545, the contactor 554 of the relay 535, conductor 555, contactor 555 of the relay 535, conductor 551, the adjustable resistor 558, the winding 559 of the polarized relay 541, and the conductor 323 to the common conductor 3H3. The adjustable resistor 555 is so adjusted that the energization of the polarized winding 559 in combination with the spring 520 balances the contactors 5 !5 and 5!9 between their respective contact terminals. Under this balanced condition of the polarized relay 541 the relays 545 and 595 are both de-energized which means that the pilot motor 540 is stopped. The circuit for energizing the polarized winding 553 may be traced as follows; beginning with the vertical common conductors 309 on Figure 4 current flows through a conductor 548, contactor 554 of the relay 535, conductor 555, contactor 555 of the relay 535, conductor 551, a fixed resistor 550, a manually pre-set potentiometer resistor 555, conductors 510, 32!, 322 and 323 to the common conductor 3!0. The circuit just traced, however, does not directly energize the polarized winding 553 but does establish for energizing, a circuit at the po-' tentiometer resistor 55! which in combination with the resistor 541 upon the motor operated rheostat establishes a balanced circuit which governs the winding 553 of the polarized relay 541. That is to say, when the resistance of the potentiometer resistor 55!, as determined by the pre-setting of the pointer and the resistance 514, as determined by the position of the movable [parts 483 of the motorized rheostat are balanced, then no current flows through the polarized winding 553 of the polarized relay 541. With this arrangement, the polarized relay 553 is in the balanced circuit of the bridge comprising the adjustable pre-set resistor 55! and the resistor 541 of the motor operated rheostat. Up until the movable part 453 moves to the left of the point 513 upon the motorized rheostat, the balanced circuit including the polarized winding 553 may be traced as follows; beginning with the preset resistor 55! current flows through a fixed resistor 552, the winding 553 of the polarized relay 541, conductor 554, the sliding bar 555 of the motor operated rheostat, a contact point 513, conductor 52!, contactor 522 of the relay 223, and conductor 523 and the resistor 514 of the motor operated rheostat to the common conductor 3 l0. Inasmuch as the bridge circuit is unbalanced when the movable part 453 of the motor operated rheostat is in its standstill position and remains unbalanced until the resistancel541, as shorted out by the movable part 453, equals to the resistance of the pre-set rheostat 55!, the polarized winding 553 is energized in such direction as to close the contact H5 or the polarized relay 541 for establishing a circuit iorenergizing the relay 545 to establish a motor circuit for energizing the pilot motor 544 to operate the movable part 453 of the motor operated rheostat to the right. The circuit for energizing the relay 543 may be traced as follows; beginning with the vertical common conductor 309 on Figure 4 current flows through conductor 545, contactor 554 of the relay.

535, conductor 525, contactor 5!8 of the polarized relay 541, conductor 525 to conductor 521 and 524 where the circuit divides, one circuit going through contactor. 525 of the relay !59 to conductor 529 and the other circuit going through the contactor 525 of the relay 23! and conductor 5!3 to conductor 529, contactor 530 Of the relay 595, the winding of the relay 545, the fast limit switch 53!, and resistor 532 to the common conductor 3!0, The limit switch 53! is actuated by a dog 534 through the dash-dot line 533, so that should the movable part 433 reach the right hand edge of the motor operated rheostat, the fast limit switch 53! is open to arrest the motor 544.

As the pilot motor 544 is energized, it actuates the movable part 453 to the right and when the movable part reaches a position upon the resistor 541 such that the shunted out portion of the resistor 541 equals the pre-setting of the resistor 55! a balanced circuit results, with no current flows through the balanced circuit {or energizing the relay 553, in which event the relay 545 becomes de-energized and the movement of the motor 544 is arrested. Therefore, the movement of the movable part 453 of the motor operated rheostat to the right is determined by the presetting of the resistor 55!. The purpose of the relay 555 which is also in the balanced circuit parallel with the polarized winding 553is to open the contactor 551 and insert the resistance 552 in series with the polarized winding 553 to make the energizing action of the polarized winding 553 positive. In the event that the operator desires to lower the speed of the equipment, he may do so by moving the pre-set resistor 55! to include less resistance for the bridge circuit, in which event an unbalanced current will flow through the polarized winding 553 in the reverse direction to close the contactor 5!9 which establishes a circuit for energizing the relay 595 to reverse the direction of the operation or the pilot motor 544 to operate the movable part 453 to the left. The circuit for energizing the relay 555 through the polarized relay 541 may be traced as follows; beginning with the vertical common conductor 309 on Figure 4 current flows through conductor 545, contactor 554, conductor 525, contactor N5 of the polarized relay 541, conductor 535, contactor 535 of the relay 545 which is de-energized, a slow limit switch 531 which is closed, the winding of the relay 555, conductor 540, and resistor 532 to the common conductor 3!0, The limit switch 531 is designated as a slow limit switch and is actuated by a dog 535 through a dash-dot line 539, That is to say, when the movable part 453 of the motor operated rheostat !31 is moved to the left to'its standstill position, the dog 533 opens the limit switch 531, but that just as soon as the movable part 435 leaves the standstill position the dog 535 closes the limit switch 531. Just as soon as the relay 555 is energized, the pilot motor 544 begins to o erate to actuate the movable part 453 of the motor operated rheostat !31 to the left until a balanced position is reached in v the bridge circuit including the resistors 55! and 514.

As the movable part 453 or the motor operated rheostat I31 moves to the right and engages the second contact point 513 a circuit is established for bridging the gap between the first and second contact points for continuously energizing the relay 453 through a contactor 445 thereof. The circuit extends from the slide bar 550, conductor 68I, contactor 449, conductor 618, resistor 409, the winding of the relay 453 and conductor 488 to the common conductor 3I0.

As the movable part 483 of the motor operated rheostat I31 moves further to the right upon the depressing of the run fast push button I50, a transition point is reached between the contact points MI and 642 for transferring the main motor 54 from the threading generator 11 to the main generator 16. Up until the contact point 46I is not reached by the movable part 483, the relay I59 is energized which connects the starting generator 11 in circuit relation with the main driving motor 54. The circuit for energizing the relay I59 may be traced as follows; beginning with the vertical common line 309 on Figure 4 current flows through conductor 430, the slide bar 43| Of the motor operated rheostat, the bridging conductors 432 and 5|0 to the contact point 5| I,

i conductors 5I2 and 5|3, the winding of the relay I59, conductor 5|4, contactor 5 I 5 of the relay 23 I, conductors 5| 6 and 5 I1, contactor 5| 8 of the relay 4| I, conductors 5I9 and 520, contactor 509 of the relay I13, conductors 52I and 498, contactor" 499 of the relay 453 and conductor; 500 to the common conductor 3I0. As the movable part 493 passes over the gap to the contact 643, the circuit is interrupted for energizing the relay I59 and thus the main motor 54 is disconnected from the threading generator 11 As soon as the movable part 483 makes contact with the contact point 642 a circuit is established for energizing the relay 23!, which connects the main motor 54 in circuit relation with the main generator 16. The circuit for energizing the relay 23| may be traced as follows; beginning with the vertical common conductor on Figure 4 current flows through the conductor 430, the slide bar 43I of the motor operated rheostat I31, the bridging conductors 432 and 5I0, to the contact point 642, the slide bar 649, conductors 644, 645 and 646, the contactor 641 of the relay 228, conductors 648 and 649, the winding of the relay 2'3I, conductor 650, contactor 655, conductor 652 and 520, contactor 599 of the relay I13, contactor MI and 498, contactor 499 and conductor 560 to the common conductor am. As previously traced, the closing of the contactor 233 of the relay 23E establishes a circuit for connecting the main motor 54 in circuit relation with the armature of the main generator 16. V I

As explained with reference to Figure 2, the relays 221 and 228 are designed to govern the transition relays E59 and 23| so that the transition is not efiected until the differential voltage between the threading generator 11 and the main generator 16 is less than 5 volts, being substantially the condition when the movable part 483 of the motor operated rheostat passes between the contacts MI and 642. The relay 221 and 226 are connected in circuit relation for energization through the contactor 653 of the relay 223, which relay is energized through the ,contactors 554 and 556 of the relay 535 upon the depressing of the run fast push button I59. The circuit for energizing the relay 223 may be traced as follows; beginning with the vertical conductor 309 on Figure 4 current flows through conductor 548, contactor 554 of the relay 535, conductor 555, contactor 556 of the relay 535, conductors 551 and 569, the bridging conductor 568, through the series of connected contact points of the motor operated rheostat to contact point 658, conductor 654, resistor 655, conductor 551, the

winding of the relay 223 and conductor 658 to the common conductor 3I0 on top of Figure 5. During the initial starting of the equipment upon the depressing of the run fast push button I50,

the voltage characteristics of the threading generator 11 and the main generator 16 are such that the threading generator has a more rapid voltage rise than the main generator until the neighborhood of 35 to 40 volts is reached at which point the voltages come together. With the wide differential of voltage between the threading generator 16 and the main generator 11 during the early stages of the starting being relatively wide, the relays 221 and 228 are energized, but just as soon as the voltage of the two generators begin to come together and reach a point of less than 5 volts the two relays 221 and 228 be'come de-energized which enables the transfer relays I59 and 23| to operate. In other words, so long as the contactor 641 of the relay 228 is open resulting from a difier'ential voltage of more than 5 volts, the relay 23I cannot become energized to connect the armature of the main motor to the armature of the main generator 16. Therefore, the purpose of the relay 228 is to insure that the diflerential voltage between the threading generator 11 and the main generator 16 is less than 5 volts during the transition period in order to prevent too large a current disturbance upon the main motor which would tend to damage the cloth being printed. The relay 223 is disconnected from being energized just as soon as the movable part 483 of the motor operated rheostat passes to the right beyond the point 658 which means that the relays 228 and 221 are removed from the differential voltage of the threading generator 11 and the main generator 16 under high speed operation where the differential voltage would be large and subject the windings of the relays 221 and 228 to the large current values.

However, before the relay 228 is de-energized by the movable part 483 passing beyond the point 658 a holding circuit is established for energiz ing the relay 23| through the contact 66L The equipment continues to run with the main motor 54 energized from the main generator 16 and the speed to which the equipment attains is determined by the setting of the pre-set rheostat 56| which governs the position to which the movable part 483 of the motor operated rheostat is moved.

In stopping the equipment, the normal plan is to press the run slow push button until the speed of the equipment is brought down to a low speed and then depress the rapid stop push button 441. Just as soon as the run slow push button I49 is depressed for reducing the speed of the equipment to a low speed, the relays 535 is de-energized with the opening of the auxiliary contact 540 of the run slow push button M9. Upon the de-energization of the relay 535 all of the circuits for energizing the windings of the polarized relays 559 and 563 are likewise de-energized and a new circuit is set up for energizing the relay 596 for operating the pilot motor 554 in backward direction 483 to its standstill position. The new circuit for energizing the relay 596 may be traced as follows; beginning with the vertical common conductor 309 on Figure 4, current flows through conductor 430, the slide bar 43I, conductors 486 and 662, the contactor 663 of the relay 535, conductor 664, the slow limit switch 631 which is closed, the windin of the relay 596, the conductor 640, and the fixed resistor 632 to the common conductor M6. The motor 554 upon the to bring theinovable part 

